Axial symmetric molding glass lens, mold assembly for an axial symmetric molding glass lens, method for manufacturing a mold assembly for an axial symmetric molding glass lens and method for manufacturing an axial symmetric molding glass lens

ABSTRACT

An axial symmetric molding glass lens has a central longitudinal axis, a lens surface, an annular intermediate area and a mounting flange area. The lens surface is axial symmetric around the central longitudinal axis and is curved. The annular intermediate area is curved and axial symmetric, is formed around the lens surface and has a radius of curvature having a continuously vary modulus that decreases as the radius of curvature approaches the annular intermediate area. The mounting flange area is formed around and connects smoothly to the annular intermediate area. The axial symmetric molding glass lens has fine precision, a high production rate and a low cost.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a molding glass lens, a mold assembly, a method for manufacturing a mold assembly and a method for manufacturing a molding glass lens, and more particularly to an axial symmetric molding glass lens, a mold assembly for an axial symmetric molding glass lens, a method for manufacturing a mold assembly for an axial symmetric molding glass lens and a method for manufacturing an axial symmetric molding glass lens.

2. Description of Related Art

Lenses are core elements of optical devices such as microscopes, magnifier telescopes, digital cameras and video cameras, are manufactured in a mold that is mold with lens surfaces cut with a computer numerical control (CNC) grinding machine and are high precision lenses.

With reference to FIG. 1, most conventional hot-press molding lenses (110) provide clear and sharp images, are made of glass and are circular, and each hot-press molding lens (110) has a central lens, a mounting flange and an annular transferred area. In telescopes and microscopes with the primary function of magnifying images, the lens quality greatly affects the precision of the magnifying power and focal length.

The axial symmetric lens is circular and has an axial symmetric surface, a flat area and an annular intermediate area.

The mounting flange is formed on and protrudes radially out from the axial symmetric lens, is used to mount the hot-press molding lens (110) in an optical device and has a flat upper surface and a flat lower surface. The flat upper surface has an inner edge. The flat lower surface has an inner edge and is parallel to the flat upper surface.

The annular intermediate area is formed of the flat upper and lower surfaces respectively may be a sharp or slightly edge and often has optical discontinuities. The discontinuities cause aberrations that adversely affect images at or near the edge of the axial symmetric lens.

A conventional mold for manufacturing a hot-press molding lens (110) comprises two molds (100). The molds (100) mate with each other to form an internal cavity in which a hot-press molding lens (110) is pressed. Each mold (100) has an intermediate area, an axial symmetric lens transferring area (101) and a flat area (102).

The axial symmetric lens transferring area (101) is formed in or on the flat surface of one mold (100), may correspond to an axial symmetric lens transferring area (101) in or on the inner surface of the matching mold (100) and has a sharp or slightly edge (103). The sharp or slightly edge (103) is formed around the axial lens transferring area (101) at the inner surface.

A conventional method of manufacturing the lens comprises lathing or grinding a piece of mold with a lathe cutting tool or a grinding tool. The axial symmetric lens transferring area (101) is circular and axial symmetric, is formed in or on the inner surface of the mold and forms an outer surface on the glass to form the molding glass lens when the molten glass in the mold.

A conventional lathing or grinding process to form a mold for a glass lens from a piece of mold is implemented with a computer numerical control (CNC) lathe or grinder. The CNC lathe or grinder rotates a piece of mold, cuts a desired shape in the piece of mold and has a cutting tool or grinding tool and a computer. The computer controls the cutting tool or grinding tool to cut a specific shape in the piece of mold and has a cutting-path formula as follows. $Z = {\frac{{CY}^{2}}{1 + \sqrt{1 - {\left( {1 + K} \right)C^{2}Y^{2}}}} + {A_{2}Y^{2}} + {A_{4}Y^{4}} + \ldots + {A_{2n}Y^{2n}}}$

wherein “Z” is a vertical coordinate, “Y” is a horizontal coordinate and “A₂,” “A₄,” “A_(2n),” “C” and “K” are constants that can be adjusted.

However, the axial symmetric lens transferring area (101) connects to the flat area (102) on the mold (100) and forms a sharp edge (103) between the axial symmetric lens transferring area (101) and the flat area (102). Molten glass material is poured into the mold between the flat area (102) and the axial symmetric lens transferring area (101). However, the molten rubs against and breaks the sharp edge (103) when passing through the sharp edge (103), which decreases quality, precision and production rate of the axial symmetric lens.

Japan patent No. 1188437 discloses a mold for manufacturing a molding glass lens, which has an axial symmetric lens transferring area, a flat area and an intermediate area. The intermediate area is formed on the mold between the axial symmetric lens transferring area and the flat area, is annular and curved and has a constant radius of curvature preferably larger than 0.2 millimeter. When a glass lens is molded, molten glass flows smoothly over the intermediate area without causing aberrations in the glass or damaging the mold. The resultant glass lens has no undesired discontinuities because no sharp edge exists on or between the axial symmetric lens transferring area and flat area on the mold (100).

However, a method for manufacturing the mold described in the Japan patent comprises two distinct cutting steps instead of one. The cutting steps respectively cut the axial symmetric lens transferring area (101) and an intermediate area in the mold (100). Furthermore, the steps are implemented with two different cutting-path formulas corresponding respectively to the axial symmetric lens transferring area and intermediate area. However, two cutting-path corrections cannot be made simultaneously to the two different cutting-path formulas in CNC lathe machines currently available. Therefore, manufactures must change the cutting-path formulas for each mold (100) or sequentially cut multiple mold (100) with one cutting-path formula. Therefore, the mold has a low production rate, and the mold quality is questionable, at best.

Japan patent publication No. 2000-249812 discloses an optical glass lens, a mold and a method for manufacturing the mold. The mold has an axial symmetric lens transferring area, a flat area and an intermediate area. The intermediate surface is between the axial symmetric lens transferring surface and flat area and is curved. However, the method for manufacturing the mold also has two steps respectively with different cutting-path formulas applicable respectively to the axial symmetric lens transferring surface (101) and the intermediate area. The transferring surface and intermediate area still have to be corrected sequentially. Therefore, the mold still has insufficient precision and a low production rate.

A conventional method for manufacturing a glass lens is to put glass into a mold to form the glass lens.

To overcome the shortcomings, the present invention provides an axial symmetric molding glass lens, a mold assembly for an axial symmetric molding glass lens, a method for manufacturing a mold assembly for an axial symmetric molding glass lens and a method for manufacturing an axial symmetric molding glass lens to mitigate or obviate the aforementioned problems.

SUMMARY OF THE INVENTION

The main objective of the invention is to provide an axial symmetric molding glass lens having fine precision, a high production rate and low cost.

A mold assembly for manufacturing axial symmetric molding glass lens comprises an upper mold and a lower mold, and at least one of the profiles of the upper and lower molds has an annular, axial symmetric flat area; and a circular, axial symmetric lens transferring area; and an annular, axial symmetric intermediate area, extended from the lens transferring area and being a part of the lens transferring area, connecting smoothly and continuously the lens transferring area and the flat area, having a radius of curvature. Values of the radius of curvature vary continuously to meet the requirements to smoothly and continuously connect the lens transferring area and the flat area.

The mold assembly improves the production rate of axial symmetric molding glass lenses.

At least one of the lens transferring area of the upper or lower molds has a shape selected from a convex shape, a concave shape, a flat shape or a hybrid shape from macro aspect; wherein the intermediate area could be convex shaped, concave shaped, flat shaped or hybrid shaped according to the requirements to smoothly and continuously connect the lens transferring area and the flat area; wherein an angle between the flat area and a plane tangent to the intermediate area is less than 45° and approaches to 0° as the plane moves from the lens transferring area toward the flat area.

The upper and lower molds are made of material from a group of carbide, nitride and silicon sinter. It could have one or more protective coatings deposited on the lens transferring area. The materials of the protective coatings are selected from a group comprising gold, platinum, iridium, osmium, rhenium, silver, palladium, rhodium, ruthenium, technetium, and their alloys or ceramics thereof, diamond-like carbon and diamond.

A method for manufacturing a mold assembly for an axial symmetric molding glass lens comprises cutting at least one mold to form an area of the mold. It comprises an upper mold and a lower mold, and at least one of the profiles of the upper and lower molds has an annular, axial symmetric flat area; and a circular, axial symmetric lens transferring area; an annular, axial symmetric intermediate area, extended from the lens transferring area and being a part of the lens transferring area, connecting smoothly and continuously the lens transferring area and the flat area, having a radius of curvature. Values of the radius of curvature vary continuously to meet the requirements to smoothly and continuously connect the lens transferring area and the flat area. An angle between the flat area and the plane tangent to the intermediate area approaches to 0° as the plane moves from the lens transferring area toward the flat area.

An axial symmetric molding glass lens comprising a central longitudinal axis; a lens surface being circular and axial symmetric around the central longitudinal axis, formed on the axial symmetric molding glass lens, being curved from lens center toward the intermediate area, an annular, axial symmetric intermediate area, extended from the lens transferring area and being a part of the lens transferring area, connecting smoothly and continuously the lens transferring area and the flat area, and a mounting flange area being flat, formed on the axial symmetric molding glass lens, formed around and connecting smoothly and continuously with the annular intermediate area. Values of the radius of curvature vary continuously to meet the requirements to smoothly and continuously connect the lens transferred area and the flat mounting flange area. An angle between the flat area and the plane tangent to the intermediate area approaches to 0° as the plane moves from the lens transferring area toward the flat area.

At least one optical coating is formed on the lens selected to perform as an ultraviolet filter, an infrared filter, a visible light attenuator, and a light efficiency improving coating or a combination thereof.

A method for manufacturing an axial symmetric molding glass lens comprising hot-pressing glass pressed by a mold assembly to form an axial symmetric molding glass lens. The mold assembly has an upper mold and a lower mold, an upper mold and a lower mold, and at least one of profiles of the upper and lower molds has an annular, axial symmetric flat area; and a circular, axial symmetric lens transferring area, and an annular, axial symmetric intermediate area, extended from the lens transferring area and being a part of the lens transferring area, connecting smoothly and continuously the lens transferring area and the flat area.

The flat area, the lens transferring area and the intermediate area of the mold assembly are transferred to the glass respectively to form the mounting flange area, the transferred area and the annular intermediate area on the axial symmetric molding glass lens. Values of the radius of curvature of the annular intermediate area vary continuously to meet the requirements to smoothly and continuously connect the lens transferred area and the flat area. And an angle between the flat area and the plane tangent to the intermediate area approaches to 0° as the plane moves from the lens transferring area toward the flat area.

Other objectives, advantages and novel features of the invention will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross sectional side view of a conventional mold and a conventional axial symmetric molding glass lens in accordance with the prior art;

FIG. 2A is an operational cross sectional side view of a first embodiment of a mold assembly molding an axial symmetric molding glass lens in accordance with the present invention;

FIG. 2B is a cross sectional side view of one of the upper and lower molds of the mold assembly;

FIG. 2C is a cross sectional side view of one of the upper and lower molds of the mold assembly in FIG. 2B with a two-dimensional coordinate system;

FIG. 2D is a cross sectional side view of a first embodiment of an axial symmetric molding glass lens in accordance with the present invention formed with the mold assembly

FIG. 3A is a cross sectional side view of a second embodiment of an axial symmetric molding glass lens in accordance with the present invention;

FIG. 3B an operational cross sectional side view of a second embodiment of a mold assembly in accordance with the present invention used to form an axial symmetric molding glass lens;

FIG. 3C is a cross sectional side view of an axial symmetric molding glass lens in accordance with present invention formed with the mold assembly in FIG. 3B; and

FIG. 4 is an operational front view of the cutter cutting the mold of the mold assembly in FIG. 2A.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

An axial symmetric molding glass lens, a mold assembly for an axial symmetric molding glass lens, a method for manufacturing a mold assembly for an axial symmetric molding glass lens and a method for manufacturing an axial symmetric molding glass lens in accordance with the present invention improve precision and reduce cost of the axial symmetric molding glass lens.

With reference to FIGS. 2D, 3A and 3C, the axial symmetric molding glass lens (30 a, 30 b, 30 c) has a central longitudinal axis and comprises a lens surface (40, 40 c), an annular intermediate area (41, 41 c), a mounting flange area (42) and at least one optional optical coating (45).

The lens surface is circular and axial symmetric around the central longitudinal axis, is formed on the axial symmetric molding glass lens, is curved from lens center toward the intermediate area.

The annular intermediate area (41, 41 c) is curved and axial symmetric, is formed on the axial symmetric molding glass lens (30 a, 30 b, 30 c) and is formed concentrically around and connects continuously to the lens surface (40, 40 c). The annular intermediate area (41, 41 c) may be convex or concave. Therefore, curvature through the annular intermediate area (41, 41 c) and the lens surface (40, 40 c) is continuous. The annular intermediate area (41, 41 c) has a radius of curvature (R1, R2, R3, R4) and a radial width. When the lens surface (40) is convex, the corresponding annular intermediate area (41) is concave, and when the lens surface (40 c) is concave, the corresponding annular intermediate area (41 c) is convex. Values of the radius of curvature of the annular intermediate area vary continuously to meet the requirements to smoothly and continuously connect the lens transferred area and the flat area. An angle between the flat area and the plane tangent to the intermediate area approaches to 0° as the plane moves from the lens transferring area toward the flat area.

The mounting flange area is flat, is formed on the axial symmetric molding glass lens, is formed around and connects smoothly and continuously to the annular intermediate area.

An angle between the flat area and the plane tangent to the intermediate area is less than 45° and approaches to 0° as the plane moves from the lens transferring area toward the flat area.

The at least one optical coating (45) is formed on the lens surface (40, 40 c), the annular intermediate area (41, 41 c) and the mounting flange area (42) of the axial symmetric molding glass lens (30 a, 30 b, 30 c) and may be selected from a group of an ultraviolet filter, an infrared filter, a visible light attenuator, an anti-scratch coating or a combination thereof.

With reference to FIGS. 2A, 2B and 3B, the mold assembly for an axial symmetric molding glass lens comprises an upper mold (11, 11 a) and a lower mold (12, 12 a).

The upper mold (11, 11 a) may be made of material selected from a group of carbide, nitride and silicon and has a flat area (22), a lens transferring area (20, 20 a), an intermediate area (21, 21 a) and a protective coating (25).

The flat area (22) is annular and has an inner edge. The lens transferring area (20, 20 a) is circular and axial symmetric, may be curved and convex or concave, is formed in or on the flat area of the upper mold (11, 11 a) and has an outer edge.

The intermediate area (21, 21 a) is annular, curved and axial symmetric, may be concave or convex, is formed concentrically on and connects smoothly to the lens transferring area (20) and has an inner edge, an outer edge, a radius of curvature (R1, R2, R3, R4) and a radial width. When the lens transferring area (20) is concave, the intermediate area (21) is convex. When the lens transferring area (20) is convex, the intermediate area (21) is concave. The inner edge of the intermediate area (21) connects smoothly and continuously to the outer edge of the lens transferring area (20). The outer edge of the intermediate area (21) connects smoothly to the inner edge of the flat area (22). The radius of curvature (R1, R2, R3, R4) has a modulus that continuously varies from the outer edge of the lens transferring area (20) to the inner edge of the flat area (22).

The protective coating (25) protects the upper mold (11, 11 a), is deposited on the flat area (22), the intermediate area (21) and the lens transferring area (20, 20 a) and is selected from a group comprising gold, platinum, iridium, osmium, rhenium, silver, palladium, rhodium, ruthenium, technetium and their or ceramic thereof, diamond-like carbon, and diamond.

The lower mold (12) may be made of material from a group of carbide, nitride and silicon sinter and has a flat area, a lens transferring area and an protective coating (25).

The lens transferring area is circular, may be flat or symmetric relative to the lens transferring area (20, 20 a).

The protective coating (25) protects the lower mold (12), is deposited on the flat area and the lens transferring area and is selected from a group comprising gold, platinum, iridium, osmium, rhenium, silver, palladium, rhodium, ruthenium, technetium, and their or ceramic thereof, diamond-like carbon and diamond.

A method for manufacturing the mold assembly in accordance with present invention comprises steps of cutting at least one mold (11, 11 a, 12) and depositing a protective coating (25) on the mold (11, 11 a, 12).

With further reference to FIG. 4, the cutting step comprises cutting at least one mold (11, 11 a, 12) to form a lens transferring area (20, 20 a), an intermediate area (21) and a flat area (22) with a computer numerical control (CNC) lathe machine or grinder. The CNC lathe machine or grinder rotates a workpiece around an axis of rotation and has a cutter (50) and a computer. The cutter (50) is mounted movably at a position relative to the axis of rotation of the CNC lathe machine or grinder, cuts the mold (11, 11 a, 12,) based on the position of the cutter (50) and may be a grinding wheel, a turning tool or a lathe tool. The computer has a cutting-path formula that controls the position of the cutter (50) to form the mold (11, 11 a, 12) in a desired shape corresponding to an appropriate surface of the axial symmetric molding glass lens.

With further reference to FIG. 2C, the cutting path formula positions the cutter (50) based on a two-dimensional coordinate system that is superimposed on the mold (11, 12) and has a Z-axis, a Y-axis and an origin. The Z-axis coincides with the axis of rotation of the CNC lathe machine or grinder, passes coaxially through the mold (11, 11 a, 12) and provides a radial reference for the cutting path formula. The Y-axis intersects the Z-axis at a point, is perpendicular to the Z-axis and provides a longitudinal reference for the cutting path formula. The origin is located at the point where the Z-axis and the Y-axis intersect and is positioned on the lens transferring area (20, 20 a). The cutting-path formula follows. $Z = {\frac{{CY}^{2}}{1 + \sqrt{1 - {\left( {1 + K} \right)C^{2}Y^{2}}}} + {A_{2}Y^{2}} + {A_{4}Y^{4}} + \ldots + {A_{2n}Y^{2n}}}$

where Z is a coordinate along the Z-axis, Y is a coordinate along the Y-axis and A₂, A₄, A_(2n), C and K are constants and may be adjusted.

An example of radial and longitudinal coordinates and corresponding radius of curvature on the lens transferring area (20, 20 a) and flat area (22) of a mold (11, 11 a, 12,) for an axial symmetric molding glass lens are provided in

Tables 1 and 2. TABLE 1 Constant Value 1/C 2.20878E+00 K 0.00000E+00 A₂ 0.00000E+00 A₄ −9.05511E−03  A₆ −2.70669E−02  A₈ 5.71773E−02 A₁₀ −9.75475E−02  A₁₂ 7.17599E−02 A₁₄ −2.20900E−02  Total Diameter of the Lens Transferring Area including the Intermediate Area: 1.8 mm

TABLE 2 Acute Angle between A Tangent Plane on The Radius of Coordinate Value Intermediate Area and Curvature Y (mm) Z (mm) The Flat Area (degree) (mm) 0 0 0 2.2087800 0.1 0.0022639 2.5927268 2.2144480 0.2 0.0090573 5.1760034 2.2352162 0.3 0.0203782 7.7335547 2.2788288 0.4 0.0362067 10.242083 2.3524567 0.5 0.0564919 12.672234 2.4697087 0.6 0.0811275 14.975934 2.6792588 0.7 0.109881 17.053901 3.1358269 0.8 0.1546341 19.001006 −1.137346 0.82 0.161273 17.60979 −0.686092 0.84 0.167232 15.413024 −0.441918 0.86 0.1721724 12.117336 −0.295500 0.88 0.1756538 7.3358308 −0.203584 0.9 0.1771081 0.6100025 −0.146029 0.92 0.1771081 0 ∞ 0.94 0.1771081 0 ∞

Values of the constants in Table 1 were determined by experimentation and allow the CNC lathe machine to cut the lens transferring area (20, 20 a) and flat area (22) of a mold (11, 11 a, 12) in a single, uninterrupted process. The diameter of the lens transferring area (20) extend from −0.825 millimeter (mm) to 0.825 mm along the Y-axis, the radius of curvature continuously varies, and the lens transferring area (20) is axial symmetric and curved. The radial width of the intermediate area (21) extends from 0.825 mm to 0.9 mm and from −0.825 mm to −0.9 mm on the Y-axis, the radius of curvature continuously varies, and the intermediate area (21) is axial symmetric and curved. With further reference to FIGS. 2B, 2D, the radius of curvature (R1, R2, R3, R4) at different points on the intermediate area (21) along a radial line are different. For example, points at Y-coordinates of 0.82 mm, 0.84 mm, 0.86 mm and 0.88 mm in Table 2 have radii of curvature respectively of −0.686092 mm, −0.441918 mm, −0.295500 mm and −0.203584 mm and show that the radii of curvature of the intermediate area (21) vary. An angle between the flat area (22) and a plane tangent to the intermediate area (21) is less than 45°. The angle between the flat area (22) and the plane tangent to the intermediate area (21) decreases as the plane moves from the outer edge of the lens transferring area (20) toward the inner edge of the flat area (22) and is nearly 0° at the inner edge of the flat area (22).

The depositing step comprises depositing a protective coating (25) on the lens transferring area (20, 20 a), the intermediate area (21) and the flat area (22) on each mold (11, 11 a, 12) using a deposition technique. The deposition technique is selected from a group of a physical phase deposition technique, a chemical phase deposition technique and an ion-sputtering technique.

A method for manufacturing the axial symmetric molding glass lens in accordance with the present invention comprises steps of hot-pressing glass and depositing at least one optical coating (45).

The hot-pressing step comprises steps of obtaining a glass (30), heating the glass (30) until it is malleable, placing the heated glass (30) between molds (11, 11 a, 12,) of a mold assembly, pressing the malleable glass (30) in the mold assembly to form an axial symmetric molding glass lens, removing the axial symmetric molding glass lens from the mold assembly and tempering the axial symmetric molding glass lens.

In the heating glass (30) step, the glass (30) is heated to a temperature of 300° C. to 700° C. until the glass (30) is malleable.

The pressing malleable glass (30) in the mold assembly forms the lens surface (30 a, 30 b, 30 c), the annular intermediate area (41, 41 c) and the mounting flange area (42).

Tempering the axial symmetric molding glass lens comprises heat-treating the axial symmetric molding glass lens in an oven by gradually raising and lowering the temperature.

The depositing at least one optical coating (45) comprises depositing at least one optical coating (45) on the surfaces (40, 40 c, 41, 41 c, 42) of the axial symmetric molding glass lens (30 a, 30 b, 30 c) by a deposition technique. The deposition technique is selected from a group of physical phase deposition, chemical phase deposition and an ion-sputtering.

The present invention has the following advantages.

The lens transferring area (20) smoothly connects to the intermediate area (21) of the mold (11, 12) and has no optical aberrations, because the heated glass is pressed rather than poured, turbulent flow between the lens transferring and intermediate area (20, 21) is obviated and the production rate and the precision of the axial symmetric molding glass lens increase.

The cutting-path formula with the constant value in Table 1 may be applied to simultaneously cut the lens transferring area (20) and the intermediate area (21) on the mold (11, 12) in a single step. Accordingly, a cutting-path correction may be applied simultaneously to the lens transferring area (20) and the intermediate area (21) and will not cause inconsistency between the surfaces (20, 21). Therefore, manufacturing and correction time of the mold (11, 12) is reduced and the precision and the production rate of the mold (11, 12) are improved.

Even though numerous characteristics and advantages of the present invention have been set forth in the foregoing description, together with details of the structure and function of the invention, the disclosure is illustrative only. Changes may be made in the details, especially in matters of shape, size, and arrangement of parts within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed. 

1. A mold assembly for manufacturing axial symmetric molding glass lens comprising an upper mold and a lower mold, and at least one of profiles of the upper and lower molds having an annular, axial symmetric flat area; and a circular, axial symmetric lens transferring area; and an annular, axial symmetric intermediate area, extended from the lens transferring area and being a part of the lens transferring area, connecting smoothly and continuously to the lens transferring area and the flat area, having a radius of curvature; wherein values of the radius of curvature vary continuously to meet requirements to smoothly and continuously connect the lens transferring area to the flat area.
 2. The mold assembly as claimed in claim 1, wherein at least one of the lens transferring area of the upper or lower molds has a shape selected from a convex shape, a concave shape, a flat shape or a hybrid shape from macro aspect.
 3. The mold assembly as claimed in claim 2, wherein the intermediate area is convex shaped, concave shaped, flat shaped or hybrid shaped according to requirements to smoothly and continuously connect the lens transferring area to the flat area.
 4. The mold assembly as claimed in claim 3, wherein an angle between the flat area and a plane tangent to the intermediate area is less than 45° and approaches to 0° as the plane moves from the lens transferring area toward the flat area.
 5. The mold assembly as claimed in claim 4, wherein the upper and lower molds are made of material from a group of carbide, nitride and silicon sinter.
 6. The mold assembly as claimed in claim 1, wherein it could have one or more optical coatings deposited on the lens transferring area.
 7. The mold assembly as claimed in claim 6, wherein the materials of the protective coatings are selected from a group comprising gold, platinum, iridium, osmium, rhenium, silver, palladium, rhodium, ruthenium, technetium, and their alloys or ceramics thereof, diamond-like carbon and diamond.
 8. A method for manufacturing a mold assembly for an axial symmetric molding glass lens, wherein a surface of an upper or lower mold is machined continuously by a cutter to form a flat area, a lens transferring area and an intermediate area; wherein: the flat area is annular and axial symmetric; and the lens transferring area is circular, axial symmetric; and the annular, axial symmetric intermediate area is extended from the lens transferring area and is a part of the lens transferring area, connecting smoothly and continuously to the lens transferring area and the flat area, having a radius of curvature; wherein values of the radius of curvature vary continuously to meet requirements to smoothly and continuously connect the lens transferring area to the flat area.
 9. The method as claimed in claim 8, wherein at least one of the lens transferring area of the upper or lower molds has a shape selected from a convex-shape, a concave-shape, a flat-shape or a hybrid shape from macro aspect.
 10. The method as claimed in claim 8 or 9, wherein the intermediate area is convex shaped, concave shaped, flat shaped or hybrid shaped.
 11. The method as claimed in claim 10, wherein an angle between the flat area and a plane tangent to the intermediate area is less than 45° and approaches to 0° as the plane moves from the lens transferring area toward the flat area.
 12. The method as claimed in claim 8, wherein the upper and lower molds are made of materials from a group of carbide, nitride and silicon sinter.
 13. The method as claimed in claim 8, wherein the cutter to machine the upper or lower mold surface is a turning tool or a grinding tool.
 14. The method as claimed in claim 8, wherein the materials of the protective coatings are selected from a group comprising gold, platinum, iridium, osmium, rhenium, silver, palladium, rhodium, ruthenium, technetium, and their alloys or ceramics thereof, diamond-like carbon and diamond.
 15. The mold assembly as claimed in claim 14, wherein the at least one protective coating is deposited with a deposition technique selected from Physical Vapor Deposition technique, Chemical Vapor Deposition technique or sputtering technique.
 16. An axial symmetric molding glass lens comprising: a central longitudinal axis; a lens surface being circular and axial symmetric around the central longitudinal axis, formed on the axial symmetric molding glass lens, being curved from lens center toward the intermediate area. an annular, axial symmetric intermediate area, extended from the lens transferring area and being a part of the lens transferring area, connecting smoothly and continuously to the lens transferring area and the flat area; and a mounting flange area being flat, formed on the axial symmetric molding glass lens, formed around and connecting smoothly and continuously with the annular intermediate area; wherein values of a radius of curvature vary continuously to meet requirements to smoothly and continuously connect the lens transferred area to the flat mounting flange area.
 17. The axial symmetric molding glass lens as claimed in claim 16, wherein at least one of the lens transferred area has a shape selected from a convex shape, a concave shape, a flat shape or a hybrid shape from macro aspect.
 18. The axial symmetric molding glass lens as claimed in claim 17, wherein the intermediate area could be convex shaped, concave shaped, flat shaped or hybrid shaped.
 19. The axial symmetric molding glass lens as claimed in claim 18, wherein an angle between the mounting flange area and a plane tangent to the annular transferred area is less than 45° and approaches to 0° as the plane moves from the lens area toward the mounting flange area.
 20. The axial symmetric molding glass lens as claimed in claim 16, wherein it could have at least one optical coatings deposited on the transferred area, the annular transferred area and the mounting flange area of the axial symmetric molding glass lens.
 21. The axial symmetric molding glass lens as claimed in claim 20, wherein the at least one optical coating is selected to perform as an ultraviolet filter, an infrared filter, a visible light attenuator, and a light efficiency improving coating or a combination thereof.
 22. A method for manufacturing an axial symmetric molding glass lens comprising hot-pressing glass pressed by a mold assembly to form an axial symmetric molding glass lens; wherein the mold assembly has an upper mold and a lower mold, an upper mold and a lower mold, and at least one of profiles of the upper and lower molds has an annular, axial symmetric flat area; and a circular, axial symmetric lens transferring area; and an annular, axial symmetric intermediate area, extended from the lens transferring area and being a part of the lens transferring area, connecting smoothly and continuously to the lens transferring area and the flat area wherein the flat area, the lens transferring area and the intermediate area of the mold assembly are transferred to the glass respectively to form the mounting flange area, the transferred area and the annular intermediate area on the axial symmetric molding glass lens; and wherein values of a radius of curvature of the annular intermediate area vary continuously to meet requirements to smoothly and continuously connect the lens transferred area to the flat area.
 23. The method as claimed in claim 22, wherein at least one of the lens transferred area has a shape selected from a convex shape, a concave shape, a flat shape or a hybrid shape from macro aspect.
 24. The method as claimed in claim 23, wherein the intermediate area is convex shaped, concave shaped, flat shaped or hybrid shaped according to requirements to smoothly and continuously connect the lens transferring area to the flat area.
 25. The method as claimed in claim 24, wherein an angle between the mounting flange area and a plane tangent to the annular intermediate area is less than 45° and approaches to 0° as the plane moves from the lens transferring area toward the mounting flange area.
 26. The method as claimed in claim 22 further comprising depositing at least one optical coating on the lens transferred area, the annular transition area and the mounting flange area on the axial symmetric molding glass lens selected to perform as an ultraviolet filter, an infrared filter, a visible light attenuator, and a light efficiency improving coating or a combination thereof.
 27. The method as claimed in claim 26, wherein the at least one optical coating is deposited with a technique selected from Physical Vapor Deposition technique, Chemical Vapor Deposition technique or sputtering technique. 